JP3278846B2 - Modular unit for tubular sonicator - Google Patents

Abstract

PCT No. PCT/FR92/00029 Sec. 371 Date Jul. 19, 1993 Sec. 102(e) Date Jul. 19, 1993 PCT Filed Jan. 15, 1992 PCT Pub. No. WO82/00260 PCT Pub. Date Feb. 4, 1982.Modular reactor unit for continuous ultrasonic processing of substances and/or reagents, characterized in that it comprises a tubular metallic body having a cylindrical inner surface and a straight circular cross secton, open at its feed and discharge ends, in that the surface of said tubular metallic body has, in the region of its nodal zone, a radially projecting collar coaxial to said tube, and in that at least one ultrasonic converter is radially arranged integral with said collar at the periphery of the latter, the frequency of said converter being equal to the frequency of vibration of said collar and to the frequency of longitudinal vibration of said tubular metallic body.

Description

The present invention relates to a modular unit for use in a tubular sonicator (ultrasonic reactor) and various applications of this unit in the form of a multi-reactor for various specific applications.

In the current state of the art, various sonicators for handling liquids are known. These are devices derived mainly from the technology of ultrasonic cleaning, usually in the form of a plurality of emitters (oscillators) mounted on the bottom of a thin metal tank.

Vibrating the bottom of the tank induces cavitation in the liquid in the tank, but the intensity of this cavitation diminishes further away from the source of vibration (ie, the bottom of the tank).

Another known method uses two diaphragms facing each other. Just as with the cleaning technique described above, 1.5
A large number of oscillators are arranged on two metal plates facing each other with a distance of 4 mm (referred to as a coupling distance). The liquid to be processed passes between the two oscillating plates.

Another type of ultrasonic device uses a number of oscillators mounted on the outer circumference of a metal tube. This device is capable of processing flowing liquids, but requires a large number of oscillators, cannot obtain amplitudes greater than those normally obtained with ultrasonic cleaning, and processes that come into contact with processed objects. There is a disadvantage in that when the metal tube is worn, the entire device needs to be replaced.

All of the above known techniques are substantially the same as the ultrasonic cleaning technique in which the oscillator is fixed directly to a metal diaphragm, tube or tank bottom.

Finally, there is an ultrasonic probe device for laboratory experiments. A well-known example is Sonifier, BRA
NSON and Vibracell, SONIC'S & MATER
IALS). This type of device is capable of handling small or low flow rate liquids.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a tubular ultrasonic reactor that propagates ultrasonic vibrations to process fluid flowing in the reactor coherently from a small number of oscillators using the principle of mechanical resonance.

According to the present invention, a modular unit of a sonicator (reactor) that achieves this object has been developed. The reactor modular unit comprises a tubular metal body having a cylindrical inner surface and a circular cross section, and having open ends on a supply side and a discharge side. The outer surface of the tubular metal body has a node ( In the vicinity of the nodal zone, there is provided a collar that projects radially coaxially with the tube, and at least one ultrasonic transducer (a converter that oscillates ultrasonic waves) is directed radially around the collar. It is fixed and has the characteristic that the frequency of this transducer (frequency of the ultrasonic waves emitted by the transducer) is equal to the frequency of the vibration of the collar and the frequency of the longitudinal vibration of the tubular metal body.

Other features and advantages of the present invention will become apparent from the following detailed description, taken in conjunction with the accompanying drawings, illustrating a number of specific embodiments. In the accompanying drawings: FIG. 1A is a sectional view of one reactor modular unit according to the present invention, FIG. 1B is an end view of the reactor modular unit of FIG. 1A, FIG. In-line combination of multiple reactor modular units according to the invention with one converter
-Line) shows a multi-reactor;-Fig. 3 shows multiple reactor modular units.
Figure 4 shows an in-line multi-reactor in combination with two separate transducers; Figure 4 shows an in-line multi-reactor consisting of a single modular unit with the tubular section of the reactor being extended asymmetrically; 5 shows another in-line multi-reactor combining various modular units with a plurality of transducers; FIG. 6 shows a modular unit in which the collar of the modular unit is mounted on a tubular metal body, for example by fitting. FIG. 7 shows a modular unit with its internal tubular member mounted close to the longitudinal maximum amplitude region (nodal point of stress) of the modular unit.

1A and 1B are a side view and an end view, respectively, of a reactor modular unit 10 according to the present invention,
As shown in these figures, this unit is mainly composed of three basic members. The unit 10 includes a tubular metal body 12 having a cylindrical inner surface 14 and a circular cross section. Both ends of the tubular metal body 12 (that is, its supply end 16 and its discharge end 18) are open. The material to be treated and / or the reactants flow in the direction of the arrow from end 16 to end 18. The supply and discharge ends 16, 18 may be connected to supply and discharge pipes, respectively, which may possibly be provided with pumps. All the rest of the equipment is not shown as it uses conventional units well known to those skilled in the art.

The modular unit 10 further includes a collar 20 coaxial with the tube at a position near a node on the outer surface of the tubular metal body 12,
The collar projects radially outward from the outer surface of the tubular metal body 12.

The modular unit 10 finally comprises at least one ultrasonic transducer (converter) 22, which is arranged radially and fixed to the outer periphery of the collar 20. According to the invention, the frequency of this transducer 22 is equal to the vibration frequency of the collar 20 and the longitudinal vibration frequency of the tubular metal body 12.

In practice, a conventional ultrasonic transducer 22, for example a piezoelectric oscillation type transducer, is used. This is B. Brown and JEGood
Man, High Intensity Ultrasonic
s) of the "Langevin triplet" type.

In the embodiment shown and described in FIGS. 1A and 1B, the coaxial collar 20 is machined integrally with the tubular metal body 12. In this type of embodiment, the collar 20 is connected to the outer surface of the tubular metal body 12 by a rounded fillet 24. Note that in the embodiment described here, the length of the tubular metal body 12 is equal to half the wavelength (half wavelength) at the frequency used. The frequency of the ultrasonic vibration supplied by the oscillator or the converter 22 is usually 5 to 100 KHz.
Note also that In the illustrated example,
The length of the tubular metal body is half the wavelength at the frequency of the ultrasonic vibration
Exactly equal to However, it is within the scope of the present invention to extend one or both sides of the coaxial collar 20 by a distance equal to an integral multiple of half the wavelength at the output frequency (half wavelength) using another longer tubular metal member. Is possible. For example, the metal member may be connected to the modular unit in the longitudinal maximum amplitude region (stress node) by means of screwing, pressure fitting (fitting), welding, or the like, or may be manufactured integrally therewith.

It should be remembered that the inner and outer diameters of the collar 20 determine the radial frequency of the coaxial collar 20, and that the inner diameter of the collar 20 is equal to the inner diameter of the tubular metal body 12. On the other hand, the length of the tubular metal body 12 is a multiple of a half wavelength, and this length determines the longitudinal frequency of the entire reactor.

In the embodiment shown in FIGS. 1A and 1B, one converter or oscillator 22 is used, which is electrostrictive, magnetostrictive, storage,
Alternatively, it may be of the (more general) piezoelectric type. Converter 22
Is fixed to the outer periphery of the collar 20. Preferably, the oscillator 22
Is fixed at the flat portion 26 so as to ensure complete contact between the collar and the collar 20. The mechanical connection of the two parts is advantageously effected by means of a member 28 such as a pin.

In frequency of the ultrasonic vibration generated by the transducer of the reactor modular unit 10 according to the present invention, the inner diameter d _i and outside diameter d _e of the collar 20, those skilled in the art based on the vibration frequency generated by the oscillator It can be determined as in the conventional case. For example, when the thickness of the collar 20 is about 15 mm, the relationship between the inner and outer diameters of the collar and the vibration frequency F is determined by the following equation.

In the formula, C is the speed of sound (cm / s) in the material metal of the color 20.

For example, consider a case in which an aluminum alloy collar is vibrated by a piezoelectric oscillator having a diameter of 40 mm and a frequency of 20 kHz.
In this case, assuming that the oscillator output frequency is 20 kHz, the collar has a thickness of 30 mm, an outer diameter of 130 mm, and an inner diameter of 42 mm.

This type of reactor unit works as follows.
The vibrations generated by the transducer 22 cause the collar 20 to vibrate radially, which causes longitudinal vibrations of the tubular metal body 12 having a length that is a multiple of half its wavelength. The phase when the collar 20 is compressed (compressed) corresponds to the phase when the tubular metal body 12 is elongated in the longitudinal direction. Conversely, when the collar 20 is expanded, the tubular metal body 12 is compressed in the longitudinal direction. Corresponds to the phase at the time. To achieve this result, the coaxial collar 20 needs to be located near the nodal surface of the tubular metal body 12. The reactor of the present invention uses the vibration of the inner diameter of the collar 20 in the radial direction to cause cavitation in the liquid to be processed that continuously flows inside the tubular metal body 12.

Any liquid, gas, colloid or other material to be treated must be passed through the interior of the tubular metal body 12 of the reactor by conventional means (not shown).

FIG. 2 shows an ultrasonic reactor in which the plurality of reactor modular units shown in FIGS. 1A and 1B are connected in a row. In the embodiment of FIG. 2, three modular units 10 are used to form an inline multi-reactor, but only one ultrasonic transducer 22 is used. A device of this type comprising a plurality of units may be of an integral construction or may be obtained by rigidly connecting a plurality of modular units in the longitudinal maximum amplitude region (stress node).

As shown in FIG. 3, a plurality of reactor modular units 10 connected to a plurality of converters 22 can be combined to form an in-line multi-reactor. In the embodiment shown here, three complete modular units, each with a converter 22, are used. These fully modular units are located at both ends and the center of the tubular reactor. In the example shown, an assembly in which a coaxial collar 20 is attached to the outer periphery of a tubular metal body 12 also having a half-wave length, between these full-wave modular units 10 having a half-wave length (a unit having no converter) Is arranged. In this configuration, a plurality of reactors having a length of one half wavelength and a remainder of one wavelength are described.
It is equivalent to a combination of modular units.

The operation of this type of in-line reactor is the same as the operation of the modular unit described above. At the same phase of the oscillation, simultaneous contraction and elongation of the different components will progressively be observed.

If the linearly connected ultrasonic reactor has multiple ultrasonic oscillators or transducers 22, it may be advantageous if all oscillators or transducers 22 are fed in parallel from the same generator . However, since phase inversion occurs every half wavelength, even numbers of oscillators should be out of phase with odd numbered oscillators for caution.

In the example shown in FIG. 4, the collar protrudes in the radial direction.
20 also continuously vibrates a length of tubular metal body extending the tubular member of the central modular unit on both sides. The lengths of the tubes on both sides of the central modular unit are both integral multiples of half a wavelength. The extension tube may be connected to the central modular unit in the longitudinal maximum amplitude region (stress node), for example by screwing or fitting. The arrangement need not be symmetric. As shown in FIG. 4, depending on the intended application, it may be advantageous to provide a longer or shorter tubular section upstream or downstream of the section where the ultrasonic vibrations are strong. Depending on the material of the reactor, the type of object to be treated, and of course, the nature and state of the reaction that takes place in the reactor,
In practice, a value between 1 and 10 times the half wavelength is usually chosen. For example, as shown in FIG. 4, after providing a feed port relatively close to the strong cavitation section to quickly apply the energy required to initiate the reaction, the downstream tubular section of the longer reactor (ie, It may be advantageous to have the reaction to continue at the sonic cavitation amplitude (where the amplitude and force are weaker).

Those skilled in the art will appreciate that the length of this tubular metal body 12 may be any suitable number equal to an integer multiple of half a wavelength at the frequency of the ultrasonic vibration provided by the transducer 22, depending on the specific application intended. You could choose the length.

FIG. 5 illustrates the use of a plurality of radially protruding collars 20 to provide a length of tube (one half wavelength in the example shown, but a longer tube if equal to an integral number of half wavelengths). (Length of which can be similarly adopted). The principle of operation is exactly the same.

FIG. 6 shows a modified example of the reactor modular unit according to the present invention. In this variant, the tubular metal body 12 and the coaxial collar 20 are manufactured separately, rather than being machined as an integral part. Thereby, a material having excellent acoustic characteristics such as aluminum and / or titanium alloy is used for the collar 20, and the tubular metal member 12 through which the liquid to be treated flows has a high resistance to erosion caused by ultrasonic cavitation. Material can be selected. Tubular metal members12
Can be made from a special steel such as stainless steel, for example. Further, the inner surface 14 of the tubular reactor is advantageously provided with a protective layer, for example, a ceramic coating, a high hardness metal coating, a ceramic / metal composite coating, etc., to protect it from cavitation erosion. In the example shown in FIG. 6, the collar is attached to the tubular member by suitable mechanical means to provide a rigid and uniform connection. A tight connection is essential to the reactor modular unit of the present invention, which can be achieved by mechanical means such as, for example, screwing, wedging, fitting. Also glue,
Non-mechanical means such as welding can be employed as well.

FIG. 7 shows another embodiment of the reactor modular unit of the present invention.

In this aspect, the reactor modular unit comprises:
Inside it is configured to receive a tubular member 30 tuned to the frequency of the oscillator 22, which tubular member 3
By tightening 2,34 near the longitudinal maximum amplitude region (stress node) of this unit, it vibrates from the axial mode.

In this embodiment, the tubular member 30 is clamped between two members tuned to the oscillator frequency (eg, tubular metal bodies 36 and 38 similar to that shown in FIG. 4).

The mounting tubular member 30 is advantageously a precision bearing surface (ie, 45 °) for good connection and perfect centering with the tubular members 36 and 38 that clamp it at its ends 32 and 34. As shown in FIG. 7, a clearance 40 is provided with respect to the inner diameter of the modular unit so that the tubular member 30 through which the fluid to be treated flows can expand and contract in the radial direction without restriction.

The reactor modular unit according to the present invention comprises:
It can be used to treat all types of fluids, such as liquids, gases, colloids, which flow naturally or by pumping inside the reactor. In addition, it is possible to simultaneously process liquid flowing outside due to cavitation caused by vibration of the outer surface of the collar 20, that is, it is possible to simultaneously process two different liquid flows, a liquid flowing inside the reactor and a liquid flowing outside the reactor. It should be noted.

This type of reactor can be used, for example, for many industrial applications listed below.

-Activation of chemical reactions (Grignard reaction, Barbierre reaction, etc.);-deagglomeration and washing of metal, ceramic and mineral powders;-treatment of ores;-wetting and dispersion of pigments and colorants;-promotion of gas dissolution; Degassing,-homogenization,-wire washing,-emulsification, etc.

Claims (10)

(57) [Claims] 1. A reactor modular unit for continuous sonication of materials and / or reactants, comprising:
It comprises a tubular metal body (12) having a cylindrical inner surface (14) and a circular cross section, with both the supply end (16) and the discharge end (18) open. On the outside,
A collar (20) protruding radially coaxially with the tube is provided near the node, and at least one ultrasonic transducer (22) is mounted radially around the outer periphery of the collar; The length of the tubular metal body (12) is
2) Equal to an integer multiple of half the wavelength at the frequency of the ultrasonic vibration generated by the ultrasonic vibration generated by the transducer (22), and the inner and outer diameters of the collar (20) are equal to the frequency of the ultrasonic vibration generated by the transducer (22). A reactor modular unit characterized by being equal in frequency. 2. A reactor modular unit according to claim 1, wherein the frequency of the ultrasonic vibration generated by said converter (22) is in the range of 5 to 100 kHz. 3. An ultrasonic transducer (22) having a flat portion (2) so as to ensure complete contact between the ultrasonic transducer (22) and the collar (20).
6. The collar according to claim 1, wherein the collar is fixed to the outer periphery of the collar, and the mechanical connection is performed by a pin or the like.
Or the reactor modular unit according to 2. 4. The tubular metal body (12) wherein the collar (20) is
The modular reactor unit according to any one of claims 1 to 3, wherein the modular unit is manufactured integrally with the reactor. 5. A method according to claim 1, wherein said collar is attached to said tubular metal body by any means providing a rigid connection. Reactor modular unit. 6. The color (20) is made of aluminum and / or aluminum.
6. The reactor according to claim 5, wherein said tubular metal body (12) is made of a metal material having good acoustic characteristics, such as a titanium alloy, and said metal material having good resistance to erosion caused by cavitation, such as stainless steel. Modular unit. 7. The tubular reactor according to claim 1, wherein the inner surface is coated with a ceramic, a hard metal or a ceramic / metal composite to protect the inner surface from cavitation erosion. The reactor modular unit according to any one of claims 1 to 6. 8. The modular unit according to claim 1, wherein a tubular member (30) is mounted on the inner surface of the modular unit in the vicinity of the longitudinal maximum amplitude region by a fastening means.
6. The reactor modular unit according to any one of items 5 to 5. 9. An ultrasonic reactor comprising a plurality of reactor modular units (10) according to any one of claims 1 to 8 connected in a row to form an in-line multi-reactor. . 10. An ultrasonic reactor according to claim 9, comprising a plurality of converters (22) which are fed in parallel by the same generator.